RESUMEN
Anaerobic soil disinfestation (ASD) is a nonchemical soil treatment where an easily decomposable carbon source is incorporated into soil, which is then irrigated to saturation and tarped to create anaerobic conditions, which prompts shifts in the soil microbiota from aerobes to anaerobes. ASD has been tested successfully for soilborne disease management in a variety of cropping systems but has not been sufficiently investigated in ornamentals. In this study, ASD was evaluated in soil-based and soilless substrates commonly used in specialty cut flower production using two model pathosystems: Rhizoctonia solani-Zinnia elegans and Phytophthora drechsleri-Gerbera jamesonii. Each substrate was mixed with pathogen-infested vermiculite and amended with either wheat bran, tomato pomace, or soybean meal as the carbon source. Amended substrates were incubated at 25°C for 4 weeks and used as growing substrates for the two crops mentioned above, which were monitored weekly for disease development for up to 5 weeks posttransplant. Additional experiments tested the effect of plant age and inoculum concentration in the substrate on ASD efficacy. Results showed that ASD has the potential to be deployed successfully for the control of Rhizoctonia stem rot in both substrates. Conversely, ASD was not effective at controlling Phytophthora crown rot on gerbera daisy in any of the experiments conducted in this study. More research is needed to understand the influence of carbon amendments, inoculum thresholds, and environmental conditions on ASD efficacy.
RESUMEN
Winterberries (Ilex verticillata and hybrids) are deciduous species of holly whose branches bearing colorful fruit are cut in late Fall to be used for seasonal decorations. The annual wholesale value of the woody cuts is $1.5 million nationally (NASS, 2019). In June 2021, approximately 80% of the 45 Ilex verticillata 'Maryland Beauty' potted plants, which were maintained in a container yard at The Ohio State University research farm in Columbus, OH, presented leaves with irregular necrotic lesions surrounded by a chlorotic halo. No other symptoms were present on the plants. Bacterial streaming was observed from the lesions using a compound microscope and isolations were performed after surface disinfesting small sections of leaf tissue from the border of the lesions by soaking in 10% bleach for 30 sec, rinsing twice in sterile water, macerating in sterile water, and streaking the suspension on nutrient broth yeast extract agar. Creamy white, circular, smooth, and convex colonies were recovered after incubation at 28°C for 48 h. Bacterial identification of one representative isolate was initially pursued from single colonies of a purified culture using five discriminative phenotypic tests (i.e., LOPAT: "L", levan production; "O", oxidase activity; "P", pectinolytic activity; "A", arginine dehydrolase production; "T", tobacco hypersensitive reaction), which resulted in the L+ O- P- A- T+ profile consistent with the description of Pseudomonas syringae (Lelliott et al. 1996). Molecular identification was performed based on rpoD marker amplification and sequencing using primers PsrpoD FNP1/PsrpoDnprpcr1 (Parkison et al. 2011). NCBI GenBank BLASTn comparison of the rpoD sequence (GenBank Acc. No. OP221440) shared 99.12% identity to P. syringae pv. passiflorae (AB163366.1). Whole genome sequence analysis was conducted to strengthen the classification of the isolate species. To this extent, DNA was sequenced with an iSeq 100 Illumina benchtop sequencer using Illumina DNA Prep kit and iSeq 100 i1 Reagent v2 (Illumina, Inc, REF: 20060060 and 20031371). Illumina Local Run Manager software was used for base calling, demultiplexing, and trimming of the raw reads. Unicycler v0.5.0 was used for de novo assembly of the genome (Wick et al. 2017). The assembled genome size was 5.9 Mb with 959 contigs and 10× coverage (NCBI GenBank Biosample No. SAMN30281368; Acc. No. JANQCB010000000). Average nucleotide identity (ANI) analysis was performed on the server MiGA online (Rodriguez-R et al. 2018). Subgroup identification was inconclusive (p>0.05), positioning this isolate between P. syringae pv. actinidiae (96.45% ANI) and pv. viburni (96.65% ANI) (Rodriguez-R & Konstantinidis, 2016). Both these pathovars cause leaf spots on woody plants such as kiwi and viburnum (Donati et al. 2020; Garibaldi et al. 2005). To confirm pathogenicity, three separate branches on each of two I. verticillata 'Maryland Beauty' potted plants were selected, and 5-7 individual young leaves (>2 weeks from emergence) on each branch were infiltrated with a bacterial suspension (108 CFU/mL) in sterile water (SW) using a needleless syringe by delivering 30-50 µL of suspension per infiltration point. One additional branch per plant was infiltrated with SW to serve as control. Plants were covered with a plastic bag for two days post-inoculation (DPI) and maintained in the laboratory at an average of 23°C. All inoculated leaves showed necrotic lesions two DPI while control leaves remained asymptomatic. To fulfill Koch's postulates, the bacterium was re-isolated from the symptomatic leaves six DPI and confirmed to be identical to the original isolate based on rpoD gene sequencing. To the best of our knowledge, this report signifies the first instance of P. syringae causing bacterial leaf spot on winterberry worldwide. Ornamental plant sales are based primarily on visual appeal; therefore, identification and monitoring of emerging pathogens is essential to ensure the health of the industry.
RESUMEN
Ohio is one of the top five floriculture producers in the United States, grossing over $200 million annually (NASS 2019). Within the international floriculture trade, gladiolus cut flowers represent the fifth highest grossing crop (Ahmed et al. 2002). In September 2021, the Ornamental Crops Pathology Lab at the Ohio State University received a gladiolus (Gladiolus spp.) sample of an unknown cultivar from a home garden in Franklin Co., OH where several plants had failed to grow from planted corms or were stunted and displaying symptoms of disease. Bleached, water-soaked spots with necrotic margins along the flowering stems, stunted flowers with partial necrosis, and necrotic bracts were observed on the submitted sample. Bacterial isolations were performed by surface disinfesting small sections of bract tissue from the border of a lesion by soaking in 10% bleach for 30 sec and rinsing twice in sterile water, macerating the tissue in sterile water, and streaking the suspension on nutrient agar (NA) plates. Plates were incubated at 28°C for 48 hours and the resulting colonies were purified by re-streaking a single colony on NA twice. Bacterial colony morphology on NA presented as cream-colored and shiny with an irregular form and undulate margin. Five in vitro tests were performed using one representative isolate to identify the bacterium to the genus level: (1) confirmed levan production, (2) confirmed pectinolytic activity, (3) confirmed ability to grow at 40°C, (4) inability to grow under anaerobic conditions, and (5) a negative oxidase test (Schaad et al. 2000). All test results identified the genus as Burkholderia. To identify to species level, gyrase subunit B (gyrB) and RNA polymerase subunit D (rpoD) markers were PCR amplified and sequenced using primers UP1-E/AprU, and 70F2/70R2, respectively (Maeda et al. 2006). NCBI GenBank BLASTn comparison showed that the gyrB sequence shared 99.33% identity to the type strain of B. gladioli (CP009323.1), while the rpoD sequence showed 99.53% identity (CP009322.1). Sequences were deposited in GenBank under accession numbers ON597852 (gyrB) and ON597853 (rpoD). To confirm pathogenicity, each of two Gladiolus communis 'Mini Elvira' potted plants were inoculated with two bacterial and two control treatments (3 leaves/treatment/plant) as follows: leaf infiltration with 1 mL of either (i) a distilled water-Tween 20 (0.03% v/v) bacterial suspension (106 cfu/mL) or (ii) a sterile water-Tween 20 suspension using a needle-less syringe; foliar spray with either (iii) the bacterial suspension or (iv) water-Tween suspension until run-off. Following inoculation, plants were covered for 24 hours with a plastic bag to increase humidity and favor infection and maintained in a greenhouse at an average temperature of 23°C. After 3 days, water-soaked, necrotic lesions were observed on the inoculated plants regardless of inoculation method, while control leaves remained asymptomatic. To fulfill Koch's postulates, bacteria were re-isolated from the lesions 7 days post-inoculation and confirmed to be identical to the original isolate based on rpoD gene sequencing. Bacterial scab of gladiolus was reported in Ohio in the late 1900s as caused by Pseudomonas gladioli (syn. P. marginata; Ellett, 1989). To the best of our knowledge, this report represents the first molecular identification of the causal agent as Burkholderia gladioli. In Ohio, the pathogen has also been observed causing slippery skin on onion but not officially reported in the peer-reviewed literature. Additionally, B. gladioli has been reported in other parts of the United States on orchid, corn, and rice (Keith et al. 2005; Lu et al. 2007; Nandakumar et al. 2009). Given the significant role of gladiolus within Ohio's floricultural trade, as well as the ability of this pathogen to infect other regional crops, monitoring of bacterial scab is important for floriculture and field crop growers alike.